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US9006791B2ActiveUtilityPatentIndex 92

III-nitride P-channel field effect transistor with hole carriers in the channel

Assignee: KUB FRANCIS JPriority: Mar 15, 2013Filed: Jan 31, 2014Granted: Apr 14, 2015
Est. expiryMar 15, 2033(~6.7 yrs left)· nominal 20-yr term from priority
Inventors:KUB FRANCIS JANDERSON TRAVIS JKOEHLER ANDREW DHOBART KARL D
H10P 50/646H10P 50/242H10P 30/206H10P 30/21H10P 14/3466H10P 14/3416H10P 14/3216H10P 14/24H10P 14/22H10D 64/0125H10D 64/0116H10W 10/011H10W 10/10H10D 64/514H10D 64/68H10D 62/8325H10D 84/856H10D 84/854H10D 84/0165H10D 84/0119H10D 84/85H10D 84/038H10D 84/05H10D 64/256H10D 64/251H10D 64/117H10D 64/62H10D 62/8503H10D 62/854H10D 62/852H10D 62/824H10D 62/605H10D 62/405H10D 62/357H10D 62/85H10D 30/4755H10D 30/4735H10D 30/4732H10D 30/611H10D 30/475H10D 30/473H10D 30/472H10D 30/60H10D 30/47H10D 30/021H10D 30/015H10D 30/014H10D 84/86H01L 29/7781H01L 29/1075H01L 29/2003H01L 29/66477H01L 29/42364H01L 29/1608H01L 29/41725H01L 29/7784H01L 29/78H01L 29/66439H10P 30/28
92
PatentIndex Score
12
Cited by
17
References
15
Claims

Abstract

A non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel comprising a nitrogen-polar III-Nitride first material, a barrier material layer, a two-dimensional hole gas in the barrier layer, and wherein the nitrogen-polar III-Nitride material comprises one or more III-Nitride epitaxial material layers grown in such a manner that when GaN is epitaxially grown the top surface of the epitaxial layer is nitrogen-polar. A method of making a P-channel III-nitride field effect transistor with hole carriers in the channel comprising selecting a face or offcut orientation of a substrate so that the nitrogen-polar (001) face is the dominant face, growing a nucleation layer, growing a GaN epitaxial layer, doping the epitaxial layer, growing a barrier layer, etching the GaN, forming contacts, performing device isolation, defining a gate opening, depositing and defining gate metal, making a contact window, depositing and defining a thick metal.

Claims

exact text as granted — not AI-modified
What we claim is: 
     
       1. A non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel comprising:
 a nitrogen-polar III-Nitride first material layer grown epitaxially on a substrate; 
 a p-type layer or region in the first material layer; 
 a barrier material layer; 
 a two-dimensional hole gas in the first material at the heterointerface of the barrier layer; and 
 wherein the p-type region in the first material layer supplies hole carriers to the two-dimensional hole gas in the first material layer at the heterointerface of the barrier layer; 
 wherein the nitrogen-polar III-Nitride material comprises one or more III-Nitride epitaxial material layers grown in such a manner that when GaN is epitaxially grown the top surface of the epitaxial layer is nitrogen-polar; 
 wherein p-type doped layers optimize the band diagram within the III-nitride material so that the valence band maximum at the heterointerface where the two dimensional hole gas is located is at a potential that is higher than the quasi-Fermi level for zero bias applied to a gate electrode; 
 wherein the two-dimensional hole gas is at a heterointerface on the side of the first layer closest to the barrier layer; and 
 further including a p-type dopant hole carrier generation layer; 
 wherein the p-type dopant hole carrier generation layer is a delta doped p-type layer within the first material or is within one or more of the epitaxial layers within the first material or is an ion implanted p-type layer. 
 
     
     
       2. The non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel of  claim 1  wherein the substrate is one selected from the group consisting of a carbon-face SiC substrate, a sapphire substrate without an AlN buffer, and a gallium nitride bulk substrate with the nitrogen-polar surface selected for epitaxial growth of the nitrogen-polar III-Nitride epitaxial layers. 
     
     
       3. The non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel of  claim 2  wherein the P-type dopant hole carrier generation layer is a III-nitride material doped with magnesium. 
     
     
       4. The non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel of  claim 2  wherein the first material comprises one or more III-nitride epitaxial layers. 
     
     
       5. The non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel of  claim 4  wherein the first material comprises III-nitride material that forms a nucleation layer on the substrate, a buffer layer, an insulating buffer layer, a insulating high voltage buffer layer, a back barrier layer, or a channel layer. 
     
     
       6. The non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel of  claim 5  further including an epitaxial channel layer. 
     
     
       7. The non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel of  claim 6  wherein the channel layer is selected to have a P-type doping concentration that is lower then P-type doping concentration for other layers within the first material so that there is reduced neutral impurity scattering of the hole carriers. 
     
     
       8. The non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel of  claim 7  wherein the epitaxial channel layer is selected to be an unintentionally doped III-nitride epitaxial layer. 
     
     
       9. The non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel of  claim 8  wherein the III-nitride barrier layer is one selected from the group consisting of AlGaN layer, InAlN layer, and InAlGaN epitaxial layer. 
     
     
       10. The non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel of  claim 9  wherein the InAlN epitaxial layer has about 17 percent indium. 
     
     
       11. The non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel of  claim 10  wherein the AlGaN layer has an aluminum concentration selected to be approximately 30 percent aluminum concentration and the AlGaN layer has a thickness of from about 5 nm to about 40 nm. 
     
     
       12. The non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel of  claim 11  wherein the two dimensional hole gas is a carrier layer at the heterointerface of a smaller bandgap material with a wider bandgap material and contains a sheet hole concentration in excess of 10 13  carriers/cm 2 . 
     
     
       13. A method of making a P-channel III-nitride field effect transistor with hole carriers in the channel comprising:
 selecting a face or offcut orientation of a silicon, sapphire, SiC, GaN, or AN substrate so that the nitrogen-polar (000-1) face is the dominant face that results for growth of III-Nitride material; 
 growing a AlN, AlGaN, or GaN nucleation layer on the silicon, sapphire, SiC, GaN, or AlN substrate in such a manner that the nitrogen-polar (000-1) face is the dominant face for growth of III-Nitride epitaxial layer growth material; 
 growing a GaN epitaxial layer by MOCVD, MBE, or atomic layer epitaxy on the nitrogen-polar (000-1) III-nitride nucleation layer; 
 doping the GaN epitaxial layer; 
 growing a III-nitride epitaxial barrier layer; 
 etching the GaN; 
 forming a source/drain ohmic contact; 
 performing device isolation by oxygen or proton ion implant or alternately by etching a mesa through the barrier material layer; 
 defining a gate opening in a second insulator layer if the second insulator layer is present; 
 depositing and defining gate metal; 
 performing a photolithography step by adding a photolithography resist material to define the contact region; 
 removing the photolithography resist material and using the metal layer or the nucleation resist material as etch resistant material for defining the contact region for the III-nitride material; 
 making a contact window through a first insulator layer to ohmic contact metal if first insulator layer is deposited after ohmic metal formation; and 
 depositing and defining a thick metal. 
 
     
     
       14. A method of making a P-channel III-nitride field effect transistor with hole carriers in the channel comprising:
 Selecting a particular face or offcut orientation of a silicon, sapphire, SiC, GaN, or AlN substrate so that the nitrogen-polar (000-1) face is the dominant face for growth of III-Nitride material or alternately grow AlN, AlGaN, or GaN nucleation layer on a silicon, sapphire, SiC, GaN, or AlN substrate in such a manner that the nitrogen-polar (000-1) face is the dominant face for growth of III-Nitride material; 
 growing epitaxially one or more nitrogen-polar III-Nitride epitaxial material layers on the material substrate where one of more of the epitaxial growth layers form a first material, one or more of the epitaxial growth layers form a barrier layer, and optionally, one or more of the epitaxial layers form a cap layer on the surface of the barrier layer; 
 forming a metal gate; 
 forming a dielectric spacer on the edge of the gate by depositing a dielectric and then reactive ion etching the dielectric; 
 depositing a nucleation resistant material such as silicon oxide or silicon nitride on a surface of the III-nitride epitaxial layers; 
 performing a photolithography step by adding a photolithography resist material to define the contact region; 
 removing the photolithography resist material and using the metal layer or the nucleation resist material as etch resistant material for defining the contact region for the III-nitride material; 
 using reactive ion etching to etch the contact recess in the III-nitride material in a contact region through the barrier layer to or slightly beyond the heterointerface into the first material so that a direct electrical connection is formed to the two dimensional hole gas that is located at the heterointerface; 
 growing or depositing a P-type doped contact layer semiconductor material in the contact recess in the contact region in such a manner that there is direct electrical contact between the P-type doped contact layer and the two dimensional hole gas; 
 etching an optional metal layer and etching the nucleation resistant material in such a manner that the surface of the III-nitride material is not degraded; 
 depositing a metal optionally using liftoff procedure and perform a high temperature anneal to form an alloyed contact or a low temperature anneal or no anneal to form a non-alloyed contact; and 
 forming an optional insulator beneath the gate, the gate metal, the passivation material on the surface of the III-nitride material, the thick metal contact to the alloyed or non-alloyed ohmic contact. 
 
     
     
       15. A non-inverted P-channel III-nitride field effect transistor with hole carriers in the channel comprising:
 a nitrogen-polar III-Nitride first material layer grown epitaxially on a substrate; 
 a barrier material layer; 
 a p-type region in the source and drain regions; 
 a two-dimensional hole gas in the first material at the heterointerface of the barrier layer; and 
 wherein the p-type region in the source and drain supplies hole carriers to the two-dimensional hole gas in the first material layer at the heterointerface of the barrier layer; 
 wherein the nitrogen-polar III-Nitride material comprises one or more III-Nitride epitaxial material layers grown in such a manner that when GaN is epitaxially grown the top surface of the epitaxial layer is nitrogen-polar; 
 wherein p-type doped layers optimize the band diagram within the III-nitride material so that the valence band maximum at the heterointerface where the two dimensional hole gas is located is at a potential that is higher than the quasi-Fermi level for zero bias applied to a gate electrode; 
 wherein the two-dimensional hole gas is at a heterointerface on the side of the first layer closest to the barrier layer; and 
 further including a p-type dopant hole carrier generation layer; 
 wherein the p-type dopant hole carrier generation layer is a delta doped p-type layer within the first material or is within one or more of the epitaxial layers within the first material or is an ion implanted p-type layer.

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